Discovery and dynamics of a Sedna-like object with a perihelion of 66 au

Abstract

Trans-Neptunian objects (TNOs) with large perihelion distances (q > 60 au) and semi-major axes (a > 200 au) provide insights into the early evolution of the solar system and the existence of a hypothetical distant planet. These objects are still rare and their detection is challenging, yet they play a crucial role in constraining models of solar system formation. Here we report the discovery of a Sedna-like TNO, 2023\,KQ14, nicknamed `Ammonite', with q = 66 au, a = 252 au, and inclination i=11. Ammonite's orbit does not align with those of the other Sedna-like objects and fills the previously unexplained `q-gap' in the observed distribution of distant solar system objects. Simulations demonstrate that Ammonite is dynamically stable over 4.5 billion years. % with less than 1\% variation in its semi-major axis. Our analysis suggests that Ammonite and the other Sedna-like objects may have shared a primordial orbital clustering around 4.2 billion years ago. Furthermore, Ammonite's stable orbit favors larger orbits ( 500 au) rather than closer ones for a large hypothetical planet in present-day trans-Neptunian space.